Exciting to see this modern genomic approach to classification of psychiatric disorders! Hopefully this will eventually lead to potential new gene therapy targets for treatment.
Analysis of more than one million people shows that mental-health disorders fall into five clusters, each of them linked to a specific set of genetic variants.
A new study reveals how viruses that infect bacteria, called bacteriophages or “phages,” use a tiny piece of genetic material to hijack bacterial cells and make more copies of themselves.
The research shows that a very small RNA molecule, called PreS, acts like a hidden “switch” inside the bacterial cell. By flipping this switch, the virus can change how the bacterial cell works and push the infection forward.
Until now, most phage research has focused on viral proteins. This study shows that phages also use RNA molecules to quickly reprogram the host cell after the bacterial genes have already been read and bacterial messages (mRNAs) were made, adding an extra layer of control during infection.
PreS attaches to these important bacterial messages and tweaks them in a way that helps the virus copy its DNA and move more efficiently toward the stage where new viruses are produced and burst out of the cell, killing the bacterium.
Using advanced methods to map RNA–RNA interactions (termed RIL-seq), the researchers found that one of PreS’s key targets is a bacterial message that makes DnaN, a protein that plays a central role in copying DNA. By helping the cell make more DnaN, PreS gives the virus a strong head start in the infection process.
Interestingly, PreS works by changing the shape of the bacterial dnaN message.
Normally, part of this message is tightly folded, which makes it hard for the cell’s protein-making machines (ribosomes) to access. PreS binds to this folded region, opens it up, and allows ribosomes to read and translate the message more efficiently.
A great paper where Miyakawa et al. show attenuation of seizures using chemogenetics for the first time in a nonhuman primate model of epilepsy. I hope chemogenetics moves into clinical trials soon (this paper was published in 2023), it seems very promising as a therapeutic modality. [ https://www.nature.com/articles/s41467-023-36642-6](https://www.nature.com/articles/s41467-023-36642-6)
Pharmacological and surgical treatments of epilepsy can have unsatisfactory outcomes, so a more targeted and on-demand approach is desirable. Here, the authors demonstrate the usage of inhibitory chemogenetics in male nonhuman primates to attenuate the magnitude and spread of cortical seizures and subsequent body convulsions.
Temporal lobe epilepsy, which results in recurring seizures and cognitive dysfunction, is associated with premature aging of brain cells.
A new study by researchers at Georgetown University Medical Center found that this form of epilepsy can be treated in mice by either genetically or pharmaceutically eradicating the aging cells, thereby improving memory and reducing seizures as well as protecting some animals from developing epilepsy.
The study appears in the journal Annals of Neurology.
Which genes are required for turning embryonic stem cells into brain cells, and what happens when this process goes wrong? In a new study published today in Nature Neuroscience, researchers led by Prof. Sagiv Shifman from The Institute of Life Sciences at The Hebrew University of Jerusalem, in collaboration with Prof. Binnaz Yalcin from INSERM, France, used genome-wide CRISPR knockout screens to identify genes that are needed for early brain development.
The study set out to answer a straightforward question: which genes are required for the proper development of brain cells?
Using CRISPR-based gene-editing methods, the researchers systematically and individually “switched off” roughly 20,000 genes to study their role in brain development. They performed the screen in embryonic stem cells while the cells changed into brain cells. By disrupting genes one by one, the team could see which genes are required for this transition to proceed normally.
Transposable elements in cancer therapy.
Transposable elements (TEs) are a major source of immunogenic nucleic acids that can be therapeutically reactivated in cancer cells to induce a state of viral mimicry.
TE expression can trigger innate immune sensing pathways, including type I interferon responses, and promote immunogenic cell death via sensors such as RIGI, MDA5, cGAS, and Z-DNA binding protein 1.
Although initially described in the context of epigenetic therapies, viral mimicry is now recognized as a shared response to diverse cancer treatment modalities, including chemotherapies and targeted therapies.
Despite their distinct primary mechanisms, these treatments converge on TE reactivation through disruption of DNA/histone methylation, p53 activation, and perturbation of mRNA splicing.
Therapeutic resistance to chemotherapy, radiation, and targeted agents is associated with TE silencing, identifying TE repression as a targetable axis of resistance.
Combination strategies to induce immunogenic TE expression can further enhance viral mimicry and boost antitumor immunity. https://sciencemission.com/Viral-mimicry-in-cancer-therapy
Scientists studying Alzheimer’s in African Americans have uncovered a striking genetic clue that may cut across racial lines. In brain tissue from more than 200 donors, the gene ADAMTS2 was significantly more active in people with Alzheimer’s than in those without it. Even more surprising, this same gene topped the list in an independent study of White individuals. The discovery hints at a common biological pathway behind Alzheimer’s and opens the door to new treatment strategies.
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CRISPR gene editing in 2025 is no longer science fiction. From curing rare immune disorders and type 1 diabetes to lowering cholesterol and reversing blindness in mice, breakthroughs are transforming medicine today. With AI accelerating precision tools like base editing and prime editing, CRISPR not only cures diseases but also promises longer, healthier lives and maybe even longevity escape velocity.
0:00 – INTRO — First human treated with prime editing.
0:35 — The DNA Problem.
1:44 – CRISPR 1.0 — The Breakthrough.
3:19 – AI + CRISPR 2.0 & 3.0
4:47 – Epigenetic Reprogramming.
5:54 – From the Lab to the Body.
7:28 – Risks, Ethics & Power.
8:59 – The 2030 Vision.
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Part 1 – “Longevity Escape Velocity: The Race to Beat Aging by 2030″
Part 2 – “Longevity Escape Velocity 2025: Latest Research Uncovered!“
Part 3 – “Longevity Escape Velocity: How AI is making us immortal by 2030!”
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A new study reveals that bacteria can survive antibiotic treatment through two fundamentally different “shutdown modes,” not just the classic idea of dormancy. The paper is published in the journal Science Advances.
The researchers show that some cells enter a regulated, protective growth arrest, a controlled dormant state that shields them from antibiotics, while others survive in a disrupted, dysregulated growth arrest, a malfunctioning state marked by vulnerabilities, especially impaired cell membrane stability. This distinction is important because antibiotic persistence is a major cause of treatment failure and relapsing infections even when bacteria are not genetically resistant, and it has remained scientifically confusing for years, with studies reporting conflicting results.
By demonstrating that persistence can come from two distinct biological states, the work helps explain those contradictions and provides a practical path forward: different persister types may require different treatment strategies, making it possible to design more effective therapies that prevent infections from coming back.